Discrete Element Simulation of Machining Cracks in Brittle Materials during High Speed Cutting
Title | Discrete Element Simulation of Machining Cracks in Brittle Materials during High Speed Cutting PDF eBook |
Author | |
Publisher | |
Pages | 0 |
Release | 2016 |
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12th International Conference on High Speed Machining
Title | 12th International Conference on High Speed Machining PDF eBook |
Author | Ning He |
Publisher | Trans Tech Publications Ltd |
Pages | 626 |
Release | 2016-01-05 |
Genre | Technology & Engineering |
ISBN | 3035701350 |
Collection of selected, peer reviewed papers from the 12th International Conference on High Speed Machining (12th HSM), October 18-20, 2015, Nanjing, China. The 81 papers are grouped as follows: Chapter 1: Mechanism and Technology of High Speed Machining Chapter 2: Micro-Machining and Non-Traditional Machining Technologies Chapter 3: Recent Developments in High Speed Machine Tools and Cutting Tools Chapter 4: CAD/CAM/CAE Technologies in Modeling and Simulation of Processes in High Speed Machining Chapter 5: Testing, Measuring and Monitoring in Machining Processes
An Investigation of Machining Amorphous Brittle Materials
Title | An Investigation of Machining Amorphous Brittle Materials PDF eBook |
Author | Wei-Chong Chiu |
Publisher | |
Pages | 274 |
Release | 1999 |
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Discrete Element Based Numerical Simulation of Crack Formation in Brittle Material by Swelling Cement
Title | Discrete Element Based Numerical Simulation of Crack Formation in Brittle Material by Swelling Cement PDF eBook |
Author | Li Fan |
Publisher | |
Pages | 0 |
Release | 2017 |
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ISBN |
Discrete Element Based Numerical Simulation of Crack Formation in Brittle Material by Swelling Cement
Title | Discrete Element Based Numerical Simulation of Crack Formation in Brittle Material by Swelling Cement PDF eBook |
Author | |
Publisher | |
Pages | |
Release | 2017 |
Genre | |
ISBN |
Static and Dynamic Crack Propagation in Brittle Materials with XFEM
Title | Static and Dynamic Crack Propagation in Brittle Materials with XFEM PDF eBook |
Author | Fleming Petri, Wagner Carlos |
Publisher | kassel university press GmbH |
Pages | 233 |
Release | 2013-01-01 |
Genre | Mathematical models |
ISBN | 3862194361 |
The aim of this thesis is the simulation of progressive damage in brittle materials due to cracking. With this aim, the mathematical crack model will be solved using the eXtended Finite Element Method for the spatial discretization and time integration schemes for the numerical integration in the time domain. The time integration schemes considered are the Generalized-? method, the continuous GALERKIN method and the discontinuous GALERKIN method.
Simulations of Dynamic Crack Propagation in Brittle Materials Using Nodal Cohesive Forces and Continuum Damage Mechanics in the Distinct Element Code LDEC.
Title | Simulations of Dynamic Crack Propagation in Brittle Materials Using Nodal Cohesive Forces and Continuum Damage Mechanics in the Distinct Element Code LDEC. PDF eBook |
Author | |
Publisher | |
Pages | 49 |
Release | 2006 |
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Experimental data indicates that the limiting crack speed in brittle materials is less than the Rayleigh wave speed. One reason for this is that dynamic instabilities produce surface roughness and microcracks that branch from the main crack. These processes increase dissipation near the crack tip over a range of crack speeds. When the scale of observation (or mesh resolution) becomes much larger than the typical sizes of these features, effective-medium theories are required to predict the coarse-grained fracture dynamics. Two approaches to modeling these phenomena are described and used in numerical simulations. The first approach is based on cohesive elements that utilize a rate-dependent weakening law for the nodal cohesive forces. The second approach uses a continuum damage model which has a weakening effect that lowers the effective Rayleigh wave speed in the material surrounding the crack tip. Simulations in this paper show that while both models are capable of increasing the energy dissipated during fracture when the mesh size is larger than the process zone size, only the continuum damage model is able to limit the crack speed over a range of applied loads. Numerical simulations of straight-running cracks demonstrate good agreement between the theoretical predictions of the combined models and experimental data on dynamic crack propagation in brittle materials. Simulations that model crack branching are also presented.